Top-down High-resolution Mass Spectrometry of Cardiac Myosin Binding Protein C Revealed That Truncation Alters Protein Phosphorylation State

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2009 Jun 23

PMID 19541641

Citations 106

Authors

Ying Ge

Inna N Rybakova

Qingge Xu

Richard L Moss

Affiliations

Soon will be listed here.

Abstract

Cardiac myosin binding protein C (cMyBP-C), bound to the sarcomere's myosin thick filament, plays an important role in the regulation of muscle contraction. cMyBP-C is a large multidomain protein that interacts with myosin, titin, and possibly actin. Mutations in cMyBP-C are the most common known cause of heritable hypertrophic cardiomypathies. Phosphorylation of cMyBP-C plays an essential role in the normal cardiac function. cMyBP-C (142 kDa) has 81 serine and 73 threonine residues presenting a major challenge for unequivocal identification of specific phosphorylation sites. Top-down mass spectrometry, which directly analyzes intact proteins, is a powerful technique to universally observe and quantify protein posttranslational modifications without a priori knowledge. Here, we have extended top-down electron capture dissociation mass spectrometry to comprehensively characterize mouse cMyBP-C expressed in baculovirus. We have unambiguously identified all of the phosphorylation sites in the truncated (28-115 kDa) and full-length forms of cMyBP-C (142 kDa) and characterized the sequential phosphorylations, using a combination of top-down and middle-down (limited proteolysis) MS approach, which ensures full sequence coverage. Unit mass resolution and high mass accuracy (<5 ppm) have been achieved for a 115-kDa protein (the largest protein isotopically resolved to date). Remarkably, we discovered that truncations in recombinant proteins, even a seemingly minor one, can dramatically alter its phosphorylation state, which is significant because truncated recombinant proteins are routinely substituted for their full-length forms in crystal structure and functional studies. Our study provides direct evidence of alterations in the posttranslational state between the truncated and full-length recombinant proteins, which can lead to variations in structure and function.

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